EMT Airway

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Prior to applying a nonrebreathing mask on a patient with difficulty breathing, you should: A: prefill the reservoir bag to ensure delivery of 100% oxygen. B: insert a nasopharyngeal airway to maintain airway patency. C: perform a complete exam to assess the degree of hypoxia. D: set the flow rate to no more than 10 liters per minute.

A: prefill the reservoir bag to ensure delivery of 100% oxygen. Reason: After attaching the nonrebreathing mask to the oxygen source, the flowmeter should be set to between 12 and 15 L/min. The reservoir bag is then prefilled with oxygen, which will allow the delivery of high-flow oxygen. Unless the patient has a decreased level of consciousness, a nasopharyngeal airway is not required before applying a nonrebreathing mask. The need for supplemental oxygen should be determined early in your assessment; do not perform an in-depth exam before deciding to administer oxygen.

Which of the following injuries or conditions should be managed FIRST? A:Fluid drainage from both ears B:Bleeding within the oral cavity C:Bilateral fractures of the femurs D:A large open abdominal wound

B: Bleeding within the oral cavity Reason: Any injury or condition that jeopardizes the airway has priority over all else. If blood or other secretions within the mouth are not suctioned immediately, aspiration may occur; this significantly increases mortality. After securing a patent airway, control any external bleeding. Ideally, you and your partner should treat airway problems and external bleeding at the same time.

13. To obtain the MOST reliable assessment of a patient's tidal volume, you should: A: assess for retractions. B: look at the rise of the chest. C: listen for airway noises. D: count the respiratory rate.

B: look at the rise of the chest. Reason: Tidal volume is the amount of air, in milliliters, breathed into or out of the lungs in a single breath. The most effective (and practical) way to assess tidal volume is to evaluate the rise of the patient's chest. If the patient's chest rises minimally during inhalation, his or her respirations are shallow; shallow respirations reflect a reduced tidal volume.

A young woman who overdosed on heroin is unresponsive with slow, shallow breathing. As you attempt to insert an oropharyngeal airway, she begins to gag. You should: A: make sure you are using the most appropriate size of oropharyngeal airway. B: suction the patient's oropharynx as you insert a nasopharyngeal airway. C: place her on her side until she stops gagging and then suction her mouth. D: remove the oropharyngeal airway and be prepared to suction her mouth.

D: remove the oropharyngeal airway and be prepared to suction her mouth. Reason: Although uncommon, an unresponsive patient may have an active gag reflex. If an unresponsive patient begins to gag as you are attempting to insert an oropharyngeal airway, you must remove the airway immediately and be prepared to suction if vomiting should occur. Turn the patient on his or her side to facilitate drainage of secretions. Once the airway has been cleared, a nasopharyngeal airway, which is better tolerated in patients with a gag reflex, should be inserted.

Sonorous respirations are MOST rapidly corrected by: A:suctioning the oropharynx. B:inserting an oropharyngeal airway. C:initiating assisted ventilations. D:correctly positioning the head.

D:correctly positioning the head. Reason: Sonorous (snoring) respirations, which most commonly result from partial airway obstruction by the tongue, are most rapidly corrected by simply positioning the head. This involves using either the head tilt-chin lift or the jaw-thrust maneuver if trauma is suspected. To further ensure airway patency, a simple adjunct (oral or nasal airway) may need to be inserted. The patient's airway should be suctioned if a gurgling sound is heard during breathing.

How should you treat an unresponsive, uninjured patient with respirations of 16 breaths/min and good chest expansion? A: Airway adjunct and oxygen via nonrebreathing mask B: Oropharyngeal suctioning and assisted ventilations C: Jaw-thrust maneuver and frequent suctioning D: Suctioning as needed and artificial ventilations

A: Airway adjunct and oxygen via nonrebreathing mask Reason: After opening the airway of an unresponsive patient, an airway adjunct (oral or nasal airway) should be inserted to keep the tongue from occluding the posterior pharynx. Oral and nasal airways are used in conjunction with manual head positioning to help maintain a patent airway. Unresponsive patients who are breathing adequately (good rate, adequate depth [tidal volume]) should receive high-flow oxygen via nonrebreathing mask. The patient must be monitored closely for signs of inadequate breathing, which will require ventilatory assistance with a bag-mask device. Suction the oropharynx only if blood or other secretions are in the patient's mouth.

A patient has severe facial injuries, inadequate breathing, and copious secretions coming from the mouth. How should this situation be managed? A: Alternate suctioning for 15 seconds and ventilations for 2 minutes. B: Insert an oropharyngeal airway and suction until the secretions clear. C: Provide artificial ventilations and suction for 30 seconds as needed. D: Turn the patient to the side and provide continuous oral suctioning.

A: Alternate suctioning for 15 seconds and ventilations for 2 minutes. Reason: Both inadequate breathing and secretions in the mouth (ie, blood, vomitus, etc) must be addressed simultaneously. This is best accomplished by suctioning in 15-second increments, then providing assisted ventilations for 2 minutes. This pattern must be continued until the airway is clear of secretions or the airway has been definitively secured (ie, endotracheal intubation). Oral suctioning should not exceed 15 seconds in the adult. The insertion of an airway adjunct should not occur until the airway is clear of secretions or potential obstructions.

Which of the following patients is the BEST candidate for an oropharyngeal airway? A: An unresponsive trauma patient with blood draining from the nose B: An unresponsive patient with uncontrolled oropharyngeal bleeding C: Any patient that you suspect of being acutely hypoxemic D: A semiconscious patient who ingested a large quantity of aspirin

A: An unresponsive trauma patient with blood draining from the nose Reason: The oropharyngeal airway is used to keep the tongue off of the posterior pharynx and is indicated for unresponsive patients without a gag reflex. If an unresponsive patient has severe, uncontrolled oropharyngeal bleeding, your priority is to suction his or her airway in order to prevent aspiration and transport rapidly. Semiconscious patients typically have a gag reflex, although it may be somewhat depressed. Oxygen should be administered to any patient with suspected hypoxemia.

Which of the following devices is contraindicated in patients with blunt chest trauma? A: Oxygen-powered ventilator B: Oral airway C: Bag-mask device D: Nasal airway

A: Oxygen-powered ventilator Reason: The flow-restricted, oxygen-powered ventilation device (FROPVD), also referred to as an oxygen-powered ventilator or manually-triggered ventilator, should not be used in patients with chest trauma; it delivers oxygen under high pressure (40 L/min) and may worsen the patient's injury. The FROPVD is also associated with a high incidence of gastric distention. The FROPVD is also contraindicated in pediatric patients and in patients with COPD. Infants and children have small lungs; the high ventilatory pressure delivered by the FROPVD can easily cause a pneumothorax. Patients with COPD often have air trapped in their lungs; excessive ventilatory pressure may cause alveolar rupture or a pneumothorax.

In which of the following situations would you MOST likely encounter agonal gasps? A: Shortly after becoming unresponsive and pulseless B: Any patient who is unresponsive due to hypoxia C: Occlusion of the posterior pharynx by the tongue D: Significant hypoxemia, regardless of the cause

A: Shortly after becoming unresponsive and pulseless Reason: Agonal gasps are occasional, irregular, and ineffective breaths. They are commonly observed in patients shortly after they become unresponsive and pulseless (cardiac arrest). Agonal gasps may also be observed in patients with a severe brain injury or cerebral anoxia (complete absence of oxygen). Patients with agonal gasps require some form of positive-pressure ventilation. Hypoxemic and hypoxic patients typically present with tachypnea (increased respirations) in an attempt to eliminate carbon dioxide and bring in more oxygen. However, as the hypoxic patient begins to decompensate, his or her respirations often become slow (bradypnea). If the tongue is occluding the posterior pharynx, a characteristic snoring sound is typically heard.

A 60-year-old woman presents with acute respiratory distress. She is conscious and alert, but restless. Her respiratory rate is 26 breaths/min with adequate chest expansion, her breath sounds are clear to auscultation bilaterally, and her oxygen saturation is 90%. Which of the following is the MOST appropriate treatment for this patient? A: Supplemental oxygen with a nonrebreathing mask B: A nasal cannula with the flowmeter set at 4 to 6 L/min C: A nasopharyngeal airway and assisted ventilations D: A nasopharyngeal airway and supplemental oxygen

A: Supplemental oxygen with a nonrebreathing mask Reason: Although the patient is restless—a sign of hypoxemia—she is conscious and alert and able to maintain her own airway; therefore, an airway adjunct is not needed at this point. Furthermore, her respirations, although increased in rate, are producing adequate tidal volume as evidenced by adequate chest expansion. Therefore, she is not in need of assisted ventilation at this point. Considering her oxygen saturation of 90%, the most appropriate treatment would be to administer high-flow oxygen with a nonrebreathing mask and closely monitor her for signs of inadequate breathing (ie, shallow breaths [reduced tidal volume], decreased level of consciousness, cyanosis). An acutely hypoxemic patient requires more oxygen than a nasal cannula can provide.

Which of the following processes occurs during cellular/capillary gas exchange? A: The capillaries give up oxygen to the cells. B: The capillaries give up carbon dioxide to the cells. C: The cells give up oxygen to the capillaries. D: The cells receive carbon dioxide from the capillaries.

A: The capillaries give up oxygen to the cells. Reason: At the cellular level, oxygen passes across the capillary bed from the arterioles and into the cell, which is facilitated by a process called diffusion, in which oxygen (as with any gas) moves from an area of higher concentration to an area of lower concentration. At the same time, carbon dioxide crosses the capillary bed and enters the venules, where it is transported back to the lungs for reoxygenation.

When ventilating an unresponsive apneic adult with a bag-mask device, you should ensure that: A: an airway adjunct has been inserted. B: you are positioned alongside the patient. C: the pop-off relief valve is manually occluded. D: ventilations occur at a rate of 20 breaths/min.

A: an airway adjunct has been inserted. Reason: When ventilating an unresponsive apneic patient with a bag-mask device, you should ensure that an oral or nasal airway adjunct is inserted, which will keep the tongue off of the posterior pharynx. When ventilating a patient with a bag-mask device, it is best for you to be positioned at the patient's head to allow for better control of the head. Ventilations in the apneic adult with a pulse (ie, not in cardiac arrest) should be provided at a rate of 10 to 12 breaths/min (one breath every 5 to 6 seconds). Generally, only pediatric sized bag-mask devices have pop-off relief valves, which should NOT be occluded, because they help prevent overinflation of the patient's lungs.

A 22-year-old male has a shard of glass impaled in his cheek. You look inside his mouth and see minor bleeding. The patient is conscious and alert with adequate breathing. You should: A: carefully stabilize the shard of glass and allow him to suction his own mouth. B: be prepared for severe bleeding as you carefully remove the shard of glass. C: remove the shard of glass and place gauze in his mouth to control the bleeding. D: carefully remove the shard of glass in the same direction that it entered.

A: carefully stabilize the shard of glass and allow him to suction his own mouth. Reason: It remains true that you should remove an impaled object if it compromises the airway or impedes your ability to manage the airway. However, neither is the case with this patient because he has an adequate airway. He is conscious and alert and has only minor bleeding in his mouth. The safest approach, and most practical given the situation, would be to carefully stabilize the shard of glass in place; consider wrapping the exposed glass with gauze to protect yourself from getting cut. Since the patient is conscious and alert and has only minor oral bleeding, it would not be unreasonable to hand him the suction catheter and allow him to use it as needed. Be sure to instruct the patient to use the suction and not to swallow any blood. Keep in mind that if you attempt to remove the shard of glass, you risk cutting yourself and causing further injury to the patient.

Prior to your arrival, a woman experiencing an asthma attack took two puffs from her prescribed inhaler without relief. After administering supplemental oxygen, you should: A: contact medical control for further advice. B: administer one more puff from her inhaler. C: provide immediate transport to the hospital. D: perform a detailed secondary assessment.

A: contact medical control for further advice. Reason: Before assisting a patient with any medication other than oxygen, the EMT must ensure that the medication is prescribed to the patient and then obtain authorization from medical control. In this case, the physician probably will allow you to help the patient take one more puff from her inhaler. Generally, up to three puffs from an inhaler are delivered in the field. It is important for you to ask the patient how many puffs were taken from the inhaler before you arrived. The EMT must correct any airway and/or breathing problems as quickly as possible. After doing so, a secondary assessment can be performed.

Signs of inadequate breathing in an unresponsive patient include: A: cyanotic oral mucosa. B: an irregular pulse. C: symmetrical chest rise. D: warm, moist skin.

A: cyanotic oral mucosa. Reason: Signs of inadequate breathing in both responsive and unresponsive patients include a respiratory rate that is too slow (less than 12 breaths/min) or too fast (greater than 20 breaths/min); shallow (reduced tidal volume), irregular, or gasping respirations; asymmetrical (unequal) chest rise; abnormal respiratory sounds, such as wheezing, stridor, or gurgling; and abnormal skin color and condition (ie, cool or cold skin, pallor, diaphoresis, cyanosis). An irregular pulse indicates a cardiac dysrhythmia.

Shallow respirations are an indication of: A: decreased tidal volume. B: increased carbon dioxide removal. C: increased oxygen intake. D: increased minute volume.

A: decreased tidal volume. Reason: Shallow respirations are an indication of decreased tidal volume. Tidal volume is the amount of air (in milliliters [mL]) breathed into or out of the lungs in a single breath. Adequate tidal volume is needed to bring in adequate amounts of oxygen and eliminate adequate amounts of carbon dioxide. Patients with shallow breathing often need some form of positive-pressure ventilation assistance (eg, bag-mask or pocket face mask device), especially if they have a decreased mental status. Minute volume is the volume of air that is moved through the lungs per minute; it is a product of tidal volume multiplied by the respiratory rate. If tidal volume is reduced, minute volume will be reduced as well unless there is a compensatory increase in the respiratory rate.

You are dispatched to a residence for an elderly female who has possibly suffered a stroke. You find her lying supine in her bed. She is semiconscious; has vomited; and has slow, irregular breathing. You should: A: manually open her airway and suction her oropharynx. B: Insert a nasal airway and begin assisting her breathing. C: perform a head tilt-chin lift and insert an oral airway. D: administer high-flow oxygen and place her on her side.

A: manually open her airway and suction her oropharynx. Reason: This patient's airway is in immediate jeopardy! The first step in caring for any semi- or unconscious patient is to manually open the airway (eg, head tilt-chin lift, jaw-thrust) and ensure it is clear of obstructions or secretions. Because the patient has vomited, she likely has vomitus in her mouth, which must be removed with suction before she aspirates it into her lungs. Mortality increases significantly if aspiration occurs. After opening her airway and removing any vomitus or secretions from her oropharynx with suction, you should insert an airway adjunct (a nasal airway in this case; the patient is semiconscious and likely has an intact gag reflex) and begin assisting her breathing with a bag-mask device. Her respiratory effort is inadequate and should be treated with some form of positive-pressure ventilation, not a nonrebreathing mask. Placing a semi- or unconscious patient on his or her side (recovery position) is only appropriate if he or she is breathing adequately; this patient is not.

After an initial attempt to ventilate an unresponsive apneic patient fails, you reposition the patient's head and reattempt ventilation without success. You should next: A: perform chest compressions, open the airway, and look in the mouth. B: turn the patient onto his side and deliver 5 to 10 back slaps. C: perform continuous chest compressions until ALS personnel arrive. D: administer 5 to 10 abdominal thrusts and reattempt to ventilate.

A: perform chest compressions, open the airway, and look in the mouth.' Reason: If you are unable to ventilate an unresponsive, apneic patient after two attempts, you should assume that he or she has a severe (complete) foreign body airway obstruction. Immediately perform 30 chest compressions (15 compressions if two EMTs are present and the patient is an infant or child). Next, open the patient's airway and look inside the mouth. If you can see the object, attempt to remove it with your finger (never perform blind finger sweeps of the mouth). If you cannot see the object, continue chest compressions. If you are able to remove the object, reattempt to ventilate. Unless paramedics are nearby, begin transport while continuing chest compressions, opening the airway and looking in the mouth, and attempting to ventilate (if you can remove the object). Abdominal thrusts are indicated for responsive children and adults with a severe airway obstruction. Back slaps are indicated for a responsive infant with a severe airway obstruction.

As you begin ventilating an unresponsive apneic man, you hear gurgling in his upper airway. Your MOST immediate action should be to: A: quickly turn the patient onto his side so secretions can drain. B: squeeze the bag-mask device with less force and reassess. C: suction the patient's airway for no longer than 15 seconds. D: reposition the patient's airway and continue ventilations.

A: quickly turn the patient onto his side so secretions can drain. Reason: Gurgling in the airway indicates the presence of vomitus or other secretions. If this is noted, you should immediately turn the patient onto his side to allow the secretions to drain. After placing the patient on his side, suction his airway for no longer than 15 seconds. To continue ventilating a patient whose airway is full of vomitus or secretions will force the secretions into the trachea, resulting in aspiration. Aspiration significantly increases mortality!

In which of the following situations should the jaw-thrust maneuver be used? A:When the mechanism of injury is unclear B:In any patient who is in cardiac arrest C:In a patient with apnea with no signs of trauma D:In a patient who is in need of frequent suctioning

A:When the mechanism of injury is unclear Reason: The jaw-thrust maneuver should be used to open the airway any time the mechanism of injury suggests trauma or when the mechanism of injury is unclear (ie, in a patient who became unresponsive without witnesses). When performed correctly, the jaw-thrust maneuver maintains a patent airway without manipulating the spine. It should be noted, however, that if the jaw-thrust maneuver does not adequately open the patient's airway, the head tilt-chin lift maneuver should be used.

You are ventilating an apneic adult with a bag-mask device and high-flow oxygen. Her pulse rate is 130 beats/min and she has cyanosis to her face and chest. The MOST reliable indicator of adequately performed ventilations in this patient is: A:a decrease in her heart rate to 90 beats/min. B:decreased compliance with each ventilation. C:slight dissipation of her cyanosis. D:noted abdominal rise with each ventilation.

A:a decrease in her heart rate to 90 beats/min. Reason: Signs of adequate positive-pressure ventilation include an improvement in heart rate, a marked improvement in skin color, a ventilation rate that is appropriate for the patient's age, and the presence of visible chest rise with each ventilation. In the adult, tachycardia is a compensatory response to hypoxemia. Adequate ventilation with high-flow oxygen increases the oxygen content of the blood; as a result, the body's need to compensate decreases, which manifests as a decrease in heart rate. Decreased compliance (increased resistance) during ventilations indicates that the airway is blocked or that the patient's lungs are difficult to ventilate (ie, asthma, COPD, CHF). The presence of abdominal rise during positive-pressure ventilation indicates that more air is going into the stomach than into the lungs.

All of the following would cause an increased level of carbon dioxide in the arterial blood, EXCEPT: A:deep, rapid breathing. B:reduced tidal volume. C:short exhalation phase. D:slow, shallow breathing.

A:deep, rapid breathing. Reason: all of the others mean you will not be breathing hard enough to get carbon out. Labored you'll get it out Adequate oxygen intake and carbon dioxide elimination require a patent airway and adequate breathing. The level of carbon dioxide in arterial blood can rise for a number of reasons. Reduced tidal volume (shallow depth of breathing) results in insufficient oxygen intake and decreased carbon dioxide elimination. A patient who is breathing slowly (bradypnea) will also experience a decrease in oxygen intake and reduced carbon dioxide elimination. If exhalation is impaired, the body will not eliminate adequate carbon dioxide; therefore, it will accumulate in arterial blood. Deep, rapid breathing (hyperventilation), however, would likely increase carbon dioxide elimination from the body, thus lowering the carbon dioxide content of arterial blood.

An inaccurate pulse oximetry reading may be caused by: A:severe peripheral vasoconstriction. B:a heart rate greater than 100 beats/min. C:heat illnesses, such as heat stroke. D:excessive red blood cell production.

A:severe peripheral vasoconstriction. Reason: A pulse oximeter measures the percentage of hemoglobin that is saturated with oxygen. Under normal conditions, a patient's oxygen saturation (SpO2) ranges between 95% and 100% while breathing room air. Although no definitive threshold for normal SpO2 values exists, an SpO2 that is less than 95% in a nonsmoker may indicate hypoxemia. Of the factors listed, several peripheral vasoconstriction (ie, hypothermia, cigarette smoking, chronic hypoxia) would be the most likely to produce an inaccurate SpO2 reading. When the peripheral vasculature constricts, blood is shunted to the core of the body; in such cases, the pulse oximeter would likely yield a falsely low reading (or no reading at all). Other factors that can cause inaccurate readings include dark or metallic nail polish, dirty fingers, and abnormal hemoglobin binding (ie, carbon monoxide [CO] poisoning). It is important to note that the pulse oximeter is designed to detect gross abnormalities, not subtle changes, and should be used in conjunction with a thorough clinical assessment of the patient.

You are assessing a 66-year-old man who has emphysema and complains of worsened shortness of breath. He is confused, has a heart rate of 120 beats/min, and an oxygen saturation of 89%. Which of the following assessment findings should concern you the MOST? A: Worsened shortness of breath B: Confusion C: Low oxygen saturation D: Tachycardia

B: Confusion Reason: All of your assessment findings in this patient are significant. Worsened shortness of breath in a patient with a preexisting respiratory disease could indicate exacerbation of his or her condition or a new problem. Tachycardia and a low oxygen saturation (SpO2) are signs of hypoxemia, a low level of oxygen in arterial blood. Of all the patient's assessment findings, the fact that he is confused should concern you the most. A decreased level of consciousness in a patient with respiratory distress indicates that the brain is not getting enough oxygen and that carbon dioxide is accumulating in the blood. It is important to recognize the signs of hypoxemia and begin immediate treatment (eg, high-flow oxygen via a nonrebreathing mask, assisted ventilation) in order to prevent hypoxia, a dangerous condition in which the body's cells and tissues do not receive enough oxygen. Left untreated, hypoxia may cause permanent brain damage or death.

In what position would you expect a patient with severe dypsea to be in? A: Supine B: Fowler's C: Lateral recumbent D: Prone

B: Fowler's Reason: The preferred position of comfort for most patients with respiratory distress is the Fowler's position (sitting up). A prone, supine, or lateral recumbent position would make it more difficult for the patient to breathe. If a patient with severe dyspnea is willing to lie flat, the EMT should take this as an ominous sign and should be prepared to assist the patient's ventilations.

What is the function of pulmonary surfactant? A: It dilates the bronchioles in the lungs and enhances the flow of air. B: It lubricates the alveolar walls and allows them to expand and recoil. C: It carries fresh oxygen from the lungs to the left side of the heart. D: It facilitates the production of mucous, which is expelled during coughing.

B: It lubricates the alveolar walls and allows them to expand and recoil. Reason: Surfactant is a lubricant that lines the alveolar walls. It allows them to expand and recoil freely, thereby allowing for an easy exchange of oxygen and carbon dioxide. Diseases such as emphysema cause destruction of the alveolar walls and a decrease in pulmonary surfactant. This makes the normal process of breathing very difficult for these patients. Mucous-producing cells, called Goblet cells, line the trachea and larger bronchi. Provided the patient has an effective cough reflex, bacteria and other pathogens can be expelled from the body via the mucous produced by the Goblet cells.

Which of the following is the preferred initial method for providing artificial ventilations to an apneic adult? A: Two-person bag-valve-mask technique with 100% oxygen B: Mouth-to-mask technique with supplemental oxygen C: One-person bag-valve-mask technique with 100% oxygen D: Flow-restricted, oxygen-powered ventilation device

B: Mouth-to-mask technique with supplemental oxygen Reason:The preferred initial method for providing artificial ventilations is the mouth-to-mask technique with one-way valve and supplemental oxygen attached. Evidence has shown that rescuers who ventilate patients infrequently have difficulty maintaining an adequate seal with a bag-mask device. Because both of the rescuer's hands are freed up when using a pocket face mask, it is easier to maintain an adequate seal, thus providing more effective ventilations. Of course, if two rescuers are available to manage the airway, the two-person bag-mask device technique should be used. The flow-restricted, oxygen-powered ventilation device, also referred to as the manually-triggered ventilator or demand valve, requires an oxygen source to function and would thus not be practical as an initial device for providing artificial ventilations.

During your assessment of a trauma patient, you note massive facial injuries, weak radial pulses, and clammy skin. What should be your MOST immediate concern? A: Providing rapid transport to a trauma center B: Potential obstruction of the airway C: Applying 100% supplemental oxygen D: Internal bleeding and severe shock

B: Potential obstruction of the airway Reason: Any trauma patient with severe maxillofacial trauma is at an extremely high risk of airway compromise. The airway can be compromised by either mandibular fractures, in which the tongue may occlude the airway, or severe oral bleeding, in which blood clots can obstruct the airway. Correct ANY airway problems immediately upon discovery, ensure adequate ventilation and oxygenation, assess for and treat other life-threatening injuries, and prepare for rapid transport.

Which of the following yields the lowest minute volume? A: Respiratory rate of 10 breaths/min; tidal volume of 500mL B: Respiratory rate of 14 breaths/min; tidal volume of 300mL C: Respiratory rate of 16 breaths/min; tidal volume of 400mL D: Respiratory rate of 12 breaths/min; tidal volume of 500mL

B: Respiratory rate of 14 breaths/min; tidal volume of 300mL Reason: Minute volume is the amount of air moved through the lungs each minute, and is calculated by multiplying tidal volume and respiratory rate. Therefore, a respiratory rate of 14 breaths/min and a tidal volume of 300 mL would yield a minute volume of 4,200 mL (4.2 L), which is less than the sum of any of the other values listed. Minute volume is affected by tidal volume, respiratory rate, or both. An increase in tidal volume, respiratory rate, or both will cause an increase in minute volume. A decrease in tidal volume, respiratory rate, or both will cause a decrease in minute volume.

Which of the following processes occurs during inhalation? A: The diaphragm descends and the intercostal muscles relax. B: The intercostal muscles and diaphragm both contract. C: The diaphragm contracts and the intercostal muscles relax. D: The intercostal muscles relax and the diaphragm descends.

B: The intercostal muscles and diaphragm both contract. Reason: During the active process of inhalation, the diaphragm contracts, causing it to descend. This increases the vertical dimensions of the chest. At the same time, the intercostal muscles (muscles between the ribs) contract, increasing the horizontal dimensions of the chest. These two processes cause intrathoracic pressure to fall, and air rushes in to fill the lungs. The drawing of air into the lungs by the actions of these muscles is called negative-pressure ventilation.

An elderly woman with COPD presents with a decreased level of consciousness, cyanosis to her face and neck, and labored respirations. Her pulse is rapid and weak and her oxygen saturation is 76%. You should: A: avoid high-flow oxygen because this may cause her to stop breathing. B: assist her ventilations with a bag-mask device and high-flow oxygen. C: apply oxygen via nasal cannula and reassess her respiratory status. D: insert a nasal airway and give her oxygen via a nonrebreathing mask.

B: assist her ventilations with a bag-mask device and high-flow oxygen. Reason: The patient in this scenario is experiencing an exacerbation (worsening) of her COPD. Her decreased level of consciousness; cyanosis; weak, rapid pulse; low oxygen saturation (SpO2); and labored breathing clearly indicate that she is not breathing adequately. Therefore, you should assist her ventilations with a bag-mask device and high-flow oxygen; if you don't, she will continue to deteriorate, possibly to the point of cardiac arrest. If needed, insert a nasal airway adjunct to help keep her airway open. Regardless of the patient's history of COPD, you must NOT withhold oxygen from her. Respiratory depression in COPD patients who receive high-flow oxygen is highly uncommon. Death due to hypoxia, however, is very common.

You are assessing a middle-aged male who is experiencing respiratory distress. The patient has a history of emphysema and hypertension. He appears fatigued; has weak retractions; and labored, shallow breathing. Your MOST immediate action should be to: A: administer oxygen with a nonrebreathing mask. B: assist his ventilations with a bag-mask device. C: assess his oxygen saturation with a pulse oximeter. D: auscultate his breath sounds to detect wheezing.

B: assist his ventilations with a bag-mask device. Reason:Your patient is NOT breathing adequately. He is fatigued; has weak retractions; and labored, shallow breathing. If you do not treat him immediately, he may stop breathing altogether. You should begin assisting his ventilations with a bag-mask device and high-flow oxygen. After initiating ventilatory assistance, attach the pulse oximeter to assess his oxygen saturation and auscultate his breath sounds. A nonrebreathing mask is appropriate for patients with difficulty breathing who are moving air adequately; this patient is not!

You are performing abdominal thrusts on a 19-year-old male with a severe airway obstruction when he becomes unresponsive. After lowering him to the ground and placing him in a supine position, you should: A: open his airway and look inside his mouth. B: begin CPR, starting with chest compressions. C: continue abdominal thrusts until ALS arrives. D: assess for a carotid pulse for up to 10 seconds.

B: begin CPR, starting with chest compressions. Reason: A patient with a severe airway obstruction may initially be responsive and then become unresponsive during treatment. In this case, you know that an airway obstruction is the cause of his or her problem. Therefore, after placing the patient in a supine position, you should begin CPR, starting with chest compressions. Do not check for a pulse before starting chest compressions. After performing 30 chest compressions (15 compressions in infants and children when two EMTs are present), open the airway and look in the mouth. Only remove an object that you can see; do not perform a blind finger sweep in any patient. If you cannot see the object, resume chest compressions. Attempt to ventilate only if you retrieve an object from the mouth.

A young female experienced massive facial trauma and is unresponsive. After several attempts, you are unable to adequately open her airway with the jaw-thrust maneuver. You should: A: apply oxygen and reattempt the jaw-thrust maneuver. B: carefully tilt her head back and lift up on her chin. C: begin assisting her ventilations with a bag-mask device. D: insert a nasopharyngeal airway and apply oxygen.

B: carefully tilt her head back and lift up on her chin. Reason: The jaw-thrust maneuver should be used to open the airway of any trauma patient because it does not require manipulation of the neck. However, if the jaw-thrust maneuver does not adequately open the patient's airway, you should carefully perform the head tilt-chin lift maneuver. The patient's airway must be patent, regardless of the situation. After opening an unresponsive patient's airway, ensure that it is clear of secretions (suction as needed), insert an airway adjunct, and assess breathing. If the patient is breathing adequately, administer high-flow oxygen via a nonrebreathing mask. If the patient is breathing inadequately, assist his or her ventilations with a bag-mask or pocket face mask device. You should avoid the use of a nasopharyngeal airway in patients with massive head or facial trauma. If the airway is accidentally pushed through a hole caused by the fracture, it may penetrate the cranium and enter the brain.

You are assessing an elderly man with respiratory distress. He is coughing up bloody sputum and has an oxygen saturation of 85%. You auscultate his breath sounds and hear coarse crackles in all lung fields. This patient MOST likely has: A: severe bacterial pneumonia. B: congestive heart failure. C: acute onset emphysema. D: decompensated asthma.

B: congestive heart failure. Reason: This patient's signs and symptoms are classic for left-sided congestive heart failure and pulmonary edema. As the left side of the heart weakens, in which case it can no longer effectively pump blood, blood backs up into the lungs, resulting in pulmonary edema. As pulmonary edema gets worse, the patient begins coughing up pink, frothy sputum (hemoptysis). The presence of fluid in the lungs impairs the exchange of oxygen and carbon dioxide, resulting in hypoxemia and a low oxygen saturation (SpO2). Auscultation of the patient's lungs often reveals coarse crackles, which indicates the presence of fluid. Emphysema is a chronic respiratory disease, not an acute one. Furthermore, hemoptysis is not a common finding with emphysema. Likewise, patients with decompensated asthma often have markedly diminished lung sounds owing to severe bronchospasm; hemoptysis and crackles are not common. Bacterial pneumonia can cause respiratory distress; however, it usually presents with fever and diminished breath sounds to a localized area of a lung (for example, the left lower lobe).

An unresponsive 60-year-old male is apneic and has a weak, rapid pulse. His oxygen saturation reads 79%. You should: A: mildly hyperventilate him until his oxygen saturation improves. B: deliver one breath over 1 second every 5 to 6 seconds. C: ventilate at a rate of 8 to 10 breaths/min, ensuring visible chest rise. D: use a pocket face mask to deliver 12 to 20 breaths/min.

B: deliver one breath over 1 second every 5 to 6 seconds. Reason: When ventilating an apneic adult with a pulse, deliver one breath every 5 to 6 seconds (10 to 12 breaths/min). A ventilation rate of 12 to 20 breaths/min (one breath every 3 to 5 seconds) is appropriate for infants and children. Regardless of the patient's age or ventilation device you are using (eg, bag-mask device, pocket face mask), each breath should be delivered over a period of 1 second (enough to produce visible chest rise). Do not hyperventilate any patient, even mildly, as this may cause a decrease in venous return to the heart secondary to hyperinflation of the lungs. Hyperventilation also increases the risks of gastric distention, regurgitation, and aspiration. After an advanced airway device has been inserted (eg, ET tube, multilumen airway, supraglottic airway) in a cardiac arrest patient, you should no longer perform "cycles" of CPR; the compressor delivers compressions at a rate of at least 100/min and the ventilator delivers 8 to 10 breaths/min (one breath every 6 to 8 seconds). This ventilatory rate during cardiac arrest applies to all age groups, except the newborn.

An elderly man is found lying unresponsive next to his bed. The patient's wife did not witness the events that led to his unresponsiveness. You should: A: apply 100% supplemental oxygen. B: grasp the angles of the lower jaw and lift. C: assess the patient's respirations. D: tilt the head back and lift up the chin.

B: grasp the angles of the lower jaw and lift. Reason: Because this patient was found unresponsive next to the bed and his wife did not witness the event, you should assume that he fell from the bed and potentially sustained a spinal injury. Because of the potential trauma, the jaw-thrust maneuver should be used, which involves grasping the angles of the lower jaw and lifting forward without manipulating the head. Performing a head tilt-chin lift maneuver could potentially worsen a spinal injury if one exists. However, it is important to note that the head tilt-chin lift maneuver should be used if the jaw-thrust maneuver does not adequately open the patient's airway. After the airway has been opened and suctioned if needed, the patient's respirations should be assessed and managed accordingly. This may include applying supplemental oxygen with a nonrebreathing mask or assisting his ventilations.

At the peak of the inspiratory phase, the alveoli in the lungs contain: A: equal levels of oxygen and carbon dioxide. B: more oxygen than carbon dioxide. C: minimal levels of oxygen and carbon dioxide. D: high quantities of carbon dioxide.

B: more oxygen than carbon dioxide. Reason: At the peak of the inspiratory (inhalation) phase, the alveoli are filled with fresh oxygen that the patient just breathed in. During the expiratory (exhalation) phase, the oxygen moves from the alveoli to the left side of the heart and the carbon dioxide is exhaled into the atmosphere. The process of oxygen and carbon dioxide exchange in the lungs is called pulmonary (external) respiration.

The process of loading oxygen molecules onto hemoglobin molecules in the bloodstream is called: A: ventilation. B: oxygenation. C: diffusion. D: respiration.

B: oxygenation. Reason: Oxygenation is the process of loading oxygen molecules onto hemoglobin molecules in the blood. Adequate oxygenation is required for internal (cellular) respiration to take place. Diffusion is the process in which gases (oxygen and carbon dioxide) move from an area of higher concentration to an area of lower concentration. Ventilation is the act of moving air into and out of the lungs. Negative-pressure ventilation is the act of normal, unassisted breathing, and occurs when the diaphragm and intercostal muscles contract, which creates a vacuum and draws air into the lungs. Positive-pressure ventilation is the act of forcing air into the lungs, such as when you are providing rescue breathing to an apneic patient or assisting the ventilations of a patient who is breathing inadequately. Respiration is the exchange of gases between the body and its environment. Pulmonary (external) respiration occurs when gases are exchanged in the lungs and cellular (internal) respiration occurs when gases are exchanged at the cellular level.

During the inhalation phase of breathing: A: the diaphragm and intercostal muscles contract and ascend. B: pressure within the thorax decreases and air is drawn into the lungs. C: the muscles in between the ribs relax, which lifts the ribs up and out. D: air passively enters the lungs as pressure within the thorax increases.

B: pressure within the thorax decreases and air is drawn into the lungs. Reason: (Bench press all the pressure away) Inhalation is the active, muscular part of breathing. During inhalation, the diaphragm and intercostal muscles contract. When the diaphragm contracts, it moves down (descends) slightly and enlarges the thoracic cage from top to bottom. Contraction of the intercostal muscles, the muscles in between the ribs, causes the ribs to move up and out. As we inhale, the combined actions of these structures enlarge the thorax in all directions. The air pressure outside the body, called the atmospheric pressure, is normally higher than the air pressure within the thorax. As we inhale and the thoracic cage expands, the air pressure within the thorax decreases, creating a slight vacuum. This draws air in through the trachea and into the lungs, a process called negative-pressure ventilation.

The method by which you administer supplemental oxygen to a hypoxic patient depends MOSTLY on the: A: presence or absence of cyanosis. B: severity of hypoxia and adequacy of breathing. C: suspected underlying cause of the hypoxia. D: patient's level of consciousness and heart rate.

B: severity of hypoxia and adequacy of breathing. Reason: All hypoxic patients, whatever the cause of their condition, should be treated with high-flow oxygen. The method of oxygen delivery depends on the severity of the hypoxia and the adequacy of the patient's breathing. For example, a hypoxic patient who is breathing adequately (eg, normal rate, adequate tidal volume) should receive oxygen via nonrebreathing mask. However, if the patient is breathing inadequately (eg, fast or slow rate, shallow breathing [reduced tidal volume]), he or she may require ventilation assistance with a bag-mask device. The absence of cyanosis does not rule out hypoxia; cyanosis is a later sign and indicates significant hemoglobin desaturation. A patient's level of consciousness and heart rate can give you clues as to the severity of his or her hypoxia; a decreased level of consciousness and a rapid, weak pulse rate are signs of significant hypoxia.

A patient who is breathing with reduced tidal volume would MOST likely have: A: a respiratory rate of 14 breaths/min. B: shallow respirations. C: warm, moist skin. D: a prolonged inhalation phase.

B: shallow respirations. Reason: Tidal volume, a measure of the depth of breathing, is the amount of air (in milliliters [mL]) that is moved into or out of the lungs during a single breath; in the average adult male, this is about 500 mL. Tidal volume cannot be quantified (that is, it cannot be assigned a numeric value) by the EMT; however, it can be estimated by observing the adequacy of chest rise during inhalation. A patient who is breathing with reduced tidal volume will have a shallow depth of breathing; his or her chest rises minimally during inhalation. If a patient is not breathing with adequate tidal volume, he or she will eventually become hypoxemic, which will cause the skin to become cool and clammy and pale or cyanotic. Conversely, a patient with a prolonged inhalation phase (eg, taking a deep breath) would experience an increase in tidal volume. Minute volume is the amount of air moved through the lungs each minute; it is calculated by multiplying tidal volume and respiratory rate. A respiratory rate of 14 breaths/min with adequate tidal volume would result in adequate minute volume. Minute volume is affected by tidal volume, respiratory rate, or both.

Clinically, reduced tidal volume would MOST likely present with respirations that are: A: deep. B: shallow. C: eupneic. D: slow.

B: shallow. Reason: Tidal volume is the amount of air, in milliliters, that is breathed into or out of the lungs in a single breath. Shallow respirations (minimal chest rise) indicates that negative-pressure ventilation, and therefore tidal volume, is inadequate. Deep respirations (hyperpnea) would cause an increase in tidal volume. Slow respirations, especially if accompanied by a shallow depth of breathing, would lead to a reduction in minute volume. Eupnea is the medical term for normal breathing; therefore, eupneic respirations are of adequate rate, depth, and regularity.

A 50-year-old man, who fell approximately 20 feet and landed on a hard surface, is semiconscious. You should: A: check for a carotid pulse if the patient is breathing rapidly. B: stabilize his head while performing the jaw-thrust maneuver. C: gently tilt the patient's head back to assess for breathing. D: begin positive-pressure ventilations with a bag-mask device.

B: stabilize his head while performing the jaw-thrust maneuver. Reason: Because of the significant mechanism of injury (fall of greater than 15 feet), spinal injury should be assumed. The first step in managing this patient is to manually stabilize his head in a neutral position and open his airway with the jaw-thrust maneuver, both of which can be performed simultaneously. After the patient's airway is open, assess the rate and quality of his breathing and treat accordingly. The head tilt-chin lift maneuver should not be used on a patient with a possible spinal injury unless the jaw-thrust maneuver does not adequately open his or her airway. The patient in this scenario is semiconscious; therefore, he has a pulse (pulseless patients are unresponsive). If an uninjured patient is found to be unresponsive, you should quickly assess for breathing by visualizing the chest. If the patient is not breathing or only has agonal gasps, you should check for a carotid pulse.

An unresponsive man has shallow, gurgling respirations at a rate of 8 breaths/min. Initial treatment should include: A: positive-pressure ventilations. B: suctioning of the oropharynx. C: oropharyngeal airway insertion. D: oxygen via nonrebreathing mask.

B: suctioning of the oropharynx. Reason: Before breathing can be assessed, let alone managed, the airway must be cleared of any and all secretions. When you hear gurgling respirations, you should provide immediate suctioning of the oropharynx for up to 15 seconds. After the airway is clear, insert an oral or nasal airway and begin assisting his ventilations. Shallow respirations at a rate of 8 breaths/min will not produce adequate minute volume and will require ventilatory assistance. If the patient is continuously producing oral secretions, you should suction his airway for 15 seconds and then ventilate him for 2 minutes. Continue this alternating pattern until his airway is clear of secretions or an advanced airway device (ie, ET tube, multilumen airway, supraglottic airway) has been inserted.

When ventilating an apneic patient, you note decreased ventilatory compliance. This means that: A: the upper airway is blocked. B: the lungs are difficult to ventilate. C: fluid is occupying the alveoli. D: you meet no resistance when ventilating.

B: the lungs are difficult to ventilate. Reason: As it applies to artificial ventilation, compliance is the ability of the lungs to expand during ventilation. Increased ventilatory compliance means that no resistance is met when you ventilate the patient; you can ventilate the lungs with ease. Decreased ventilatory compliance means that significant resistance is met when you ventilate the patient; the lungs are difficult to ventilate. Conditions such as upper airway obstruction, widespread bronchospasm, fluid in the alveoli (eg, pulmonary edema), and COPD can all cause decreased ventilatory compliance.

A patient overdosed on several drugs and is unresponsive with shallow breathing and facial cyanosis. As you continue your assessment, the patient suddenly vomits. You should: A: suction his oropharynx at once. B: turn the patient onto his side. C: begin assisting his ventilations. D: insert an oropharyngeal airway.

B: turn the patient onto his side. Reason: The patient's airway must be clear of foreign bodies or secretions before it can be assessed or managed. If the patient begins to vomit, he must first be rolled onto his side to allow for drainage of the vomitus. Use suction to remove secretions after you have positioned him on his side. After the airway is clear, you should insert an appropriate airway adjunct (oral or nasal airway) and ensure adequate ventilation and oxygenation. In this patient, this involves assisting his ventilations with a bag-mask device.

In which position should you place an uninjured, unresponsive patient with a respiratory rate of 14 breaths/min and adequate tidal volume? A:Full-Fowler's B:Lateral recumbent C:Semi-Fowler's D:Supine

B:Lateral recumbent Reason: The recovery position, which involves placing the patient on his or her side (lateral recumbent), is used to maintain a patent airway in an unresponsive patient who is not injured AND is breathing on his or her own with a normal rate and adequate tidal volume (depth of breathing). Patients who are in shock or require positive-pressure ventilation should be placed in a supine (on his or her back) position. The semi-Fowler's position involves placing the patient in a semisitting position at a 45-degree angle; it is the position of comfort for most patients. The full-Fowler's position involves sitting the patient in an upright position at a 90-degree angle; it is often used for patients with respiratory distress.

Which of the following patients obviously needs positive-pressure ventilation assistance? A:Combative; respiratory rate of 24 breaths/min and deep B:Responsive to pain only; respiratory rate of 8 breaths/min and shallow C:Restless; respiratory rate of 12 breaths/min with adequate tidal volume D:Semiconscious; respiratory rate of 14 breaths/min and good chest rise

B:Responsive to pain only; respiratory rate of 8 breaths/min and shallow Reason: Any patient with a decreased level of consciousness should be assessed for inadequate breathing (eg, fast or slow respiratory rate, reduced tidal volume [shallow breathing]). Of the patients listed, the patient who is responsive to pain only and has shallow respirations of 8 breaths/min clearly needs positive-pressure ventilation assistance. Slow, shallow respirations will not produce the minute volume needed to support adequate oxygenation of the blood.

The MOST appropriate treatment for a semiconscious patient with slow, shallow respirations includes: A:an oropharyngeal airway and assisted ventilation with a bag-mask device. B:a nasopharyngeal airway and assisted ventilation with a bag-mask device. C:an oropharyngeal airway and high-flow oxygen via a nonrebreathing mask. D:a nasopharyngeal airway and high-flow oxygen via a nonrebreathing mask.

B:a nasopharyngeal airway and assisted ventilation with a bag-mask device. Reason: Semiconscious patients are not fully able to protect their own airway and require an airway adjunct. The nasopharyngeal airway is indicated for semiconscious patients because they often have an intact gag reflex; the oropharyngeal airway is contraindicated in any patient with an intact gag reflex. Slow, shallow respirations will not provide the minute volume needed to support adequate oxygenation and should be treated with positive-pressure ventilation assistance (eg, bag-mask device, pocket face mask). You can't apply positive-pressure ventilation assistance with a nonrebreathing mask.

The active, muscular part of breathing is called: A:expiration. B:inhalation. C:respiration. D:ventilation.

B:inhalation. Reason: The active, muscular part of breathing is called inhalation (inspiration). During inhalation, the diaphragm and intercostal muscles contract. When the diaphragm contracts, it descends and enlarges the thoracic cage from top to bottom. When the intercostal muscles contract, they lift the ribs up and out. As the thoracic cage expands, the air pressure within the thorax decreases, creating a slight vacuum. This pulls air through the trachea, causing the lungs to fill. Exhalation (expiration) does not require muscular effort; it is a passive process. During exhalation, the diaphragm and intercostal muscles relax. In response, the thorax decreases in size, and the ribs and muscles assume a normal resting position. When the size of the thoracic cage decreases, air in the lungs is compressed into a smaller space. The air pressure within the thorax then becomes higher than the pressure outside and air is pushed out through the trachea. Respiration is defined as the exchange of gases between the body and its environment. Ventilation is defined as the movement of air into and out of the lungs.

You receive a call for a 49-year-old woman who passed out. The patient's husband tells you that they were watching TV when the incident occurred. No trauma was involved. The patient is semiconscious and has cyanosis to her lips. After opening her airway with the head tilt-chin lift maneuver, you should: A:assess her respiratory effort. B:insert a nasopharyngeal airway C:insert an oropharyngeal airway. D:begin ventilation assistance.

B:insert a nasopharyngeal airway Reason: In the absence of trauma, open the patient's airway with the head tilt-chin lift maneuver. To help maintain airway patency, a nasopharyngeal airway should be inserted. Your patient is semiconscious, not unconscious, so she will likely gag if you attempt to insert an oropharyngeal airway; this may result in aspiration if she vomits. Remember, you must first open the patient's airway and, if needed, suction any secretions from the mouth. Next, insert an airway adjunct and assess respiratory effort. The method of oxygenation you provide depends on the adequacy of the patient's breathing.

The tidal volume of an unresponsive patient is rapidly assessed by: A:auscultating his or her lung sounds. B:observing for chest rise during inhalation. C:counting the patient's respiratory rate. D:evaluating for the presence of cyanosis.

B:observing for chest rise during inhalation. Reason: Tidal volume, a measure of the depth of breathing, is the amount of air in milliliters (mL) that is moved into or out of the lungs during a single breath. The average tidal volume for an adult male is approximately 500 mL. The quickest and most effective way to assess a patient's tidal volume is to observe his or her chest during breathing. If the chest rises adequately during inhalation, tidal volume is probably adequate. If the chest rises very little, as with shallow breathing, tidal volume is likely reduced. Auscultating breath sounds can give you an idea as to the patient's tidal volume; bilaterally diminished breath sounds may indicate a reduced tidal volume. It is quicker, however, to simply observe the chest for adequate rise. The presence of cyanosis indicates hypoxemia and is not a direct reflection of tidal volume.

45. When ventilating an apneic patient with a pocket mask device, each breath should be delivered over: A: 2 seconds. B: 4 seconds. C: 1 second. D: 3 seconds.

C: 1 second. Reason: When ventilating any apneic patient, each breath should be delivered over a period of 1 second—just enough to produce visible chest rise. Excessive ventilation duration and/or volume increases the likelihood of gastric distention—especially if the patient's airway is not secured with an advanced device (ie, ET tube, multilumen airway, supraglottic airway)—and may result in increased intrathoracic pressure, decreased venous return to the heart, and decreased cardiac output.

You are administering oxygen at 15 L/min to a patient with respiratory distress. If you are using a D cylinder (cylinder constant, 0.16), which reads 1,500 psi, how long will it take before you need to replace the oxygen cylinder? A: 9 minutes B: 18 minutes C: 14 minutes D: 11 minutes

C: 14 minutes Reason: The length of time you can use an oxygen cylinder depends on the type of cylinder you are using, the pressure in the cylinder, and the oxygen flow rate. A D cylinder is a small oxygen cylinder that is usually carried in the jump kit to the patient; it has a cylinder constant of 0.16. The following method can be used to calculate cylinder duration: gauge pressure (in psi) - the safe residual pressure (200 psi) × the cylinder constant ÷ flow rate in L/min. Using this formula, your D cylinder will become depleted in about 14 minutes, as follows: 1,500 (psi) - 200 (safe residual pressure) × 0.16 (cylinder constant) ÷ 15 (flow rate in L/min) = 13.86 (14 minutes). A full oxygen cylinder should contain 2,000 psi. The safe residual pressure is the lowest acceptable cylinder pressure before it should be replaced; it is usually 200 psi, although some EMS systems use 500 psi as a safe residual pressure. Although you will switch to your on-board oxygen (M cylinder) source when you load the patient into the ambulance, you should always have at least one back-up portable cylinder (preferably two) when administering oxygen to a patient at the scene, especially if you are giving high-flow (12 to 15 L/min) oxygen and/or your on-scene time will be delayed (eg, lengthy extrication, moving a patient from the second floor, etc).

Which of the following signs or symptoms is indicative of cerebral hypoxia? A: Chief complaint of dyspnea B: Heart rate greater than 120 beats/min C: Decreased level of consciousness D: Diffuse wheezing on exhalation

C: Decreased level of consciousness Reason: Dyspnea, a feeling of shortness of breath, is a symptom of a condition that can cause cerebral hypoxia (eg, CHF, COPD); however, dyspnea itself does not indicate cerebral hypoxia. Wheezing, a whistling sound that indicates bronchospasm, is a sign; like dyspnea, it indicates the presence of a condition that can cause cerebral hypoxia (eg, asthma). Tachycardia can occur for many reasons; cerebral hypoxia is but one. Of the choices listed, a decreased level of consciousness is most indicative of cerebral hypoxia. As oxygen levels in the brain decrease and carbon dioxide levels increase, the patient's mental status deteriorates.

Which of the following airway sounds indicates a lower airway obstruction? A: Gurgling B: Stridor C: Wheezing D: Crowing

C: Wheezing Reason: Wheezing is a whistling sound that results from narrowing and/or inflammation of the bronchioles in the lungs and is an indicator of a lower airway disease (ie, asthma, bronchiolitis). Crowing and stridor are both high-pitched sounds that indicate an upper airway disease or obstruction (ie, croup, epiglottitis, foreign body obstruction), and gurgling indicates secretions in the oropharynx.

A 33-year-old female presents with acute respiratory distress. She is conscious but anxious, and tells you that she has a history of asthma. She took two puffs of her albuterol inhaler prior to your arrival, but states that it did not help. Her oxygen saturation reads 89% and you hear diffuse wheezing while auscultating her lungs. You should: A: ventilate her with a bag-mask device until her oxygen saturation is at least 94% and rapidly transport her to the closest appropriate medical facility. B: give her 100% humidified oxygen to dilate her bronchioles, monitor her oxygen saturation, and transport her to an appropriate medical facility. C: administer high-flow oxygen, contact medical control to request permission to assist her with another albuterol treatment, and prepare for transport. D: assist her with a third albuterol treatment, contact medical control for further advice, give her high-flow oxygen, and transport her to the hospital.

C: administer high-flow oxygen, contact medical control to request permission to assist her with another albuterol treatment, and prepare for transport. Reason: Despite two albuterol treatments, the patient is still experiencing respiratory distress. Furthermore, the presence of wheezing indicates continued bronchospasm. After administering high-flow oxygen via a nonrebreathing mask, you should contact medical control and request permission to assist the patient with a third albuterol treatment. Drugs such as albuterol (Proventil, Ventolin) and metaproterenol (Alupent) stimulate beta-2 receptors in the lungs, resulting in bronchodilation. Up to three bronchodilator treatments are typically given in the prehospital setting. In most EMS systems, EMTs are not allowed to assist patients with their medication without medical control authorization. After assisting the patient with a third albuterol treatment, reassess her breath sounds and oxygen saturation and transport her promptly.

You are ventilating an apneic 50-year-old woman with a bag-mask device. After squeezing the bag and noting visible chest rise, you should: A: squeeze the bag again in 3 seconds. B: suction the airway for up to 15 seconds. C: allow the patient to completely exhale. D: reopen the airway and ventilate again.

C: allow the patient to completely exhale. Reason: When ventilating an apneic patient, it is important to allow for complete exhalation. To do this, deliver each breath over 1 second, just enough to make the chest visibly rise, and then deliver the next breath 5 to 6 seconds later (3 to 5 seconds later for infants and children). Failure to allow for complete exhalation may cause the patient to retain carbon dioxide (carbon dioxide elimination occurs during exhalation) and may also impair venous return to the heart secondary to hyperinflation of the lungs. If you observe visible chest rise when you ventilate the patient, there is no need to reopen the airway. Suction the airway only if secretions are present.

Hypoxia is defined as: A: decreased oxygen content in arterial blood. B: an excess amount of carbon dioxide in arterial blood. C: inadequate oxygen to the body's cells and tissues. D: an absence of oxygen to the vital body organs.

C: inadequate oxygen to the body's cells and tissues. Reason: Hypoxia is a dangerous condition in which the body's cells and tissues do not have enough oxygen. Hypoxemia is a decreased amount of oxygen in arterial blood. Untreated hypoxemia will lead to hypoxia. An absence of oxygen to any part of the body is called anoxia. An excess amount of carbon dioxide in arterial blood is called hypercarbia. If the body cannot bring in enough oxygen, it is also unable to eliminate carbon dioxide from the blood; therefore, hypoxemia and hypercarbia occur together.

Agonal respirations are not adequate because they are: A: associated with a prolonged inhalation phase. B: the result of an increase in tidal volume. C: infrequent, gasping respiratory efforts. D: characterized by a rapid, irregular pattern.

C: infrequent, gasping respiratory efforts. Reason: A patient may appear to be breathing after his or her heart has stopped. These occasional, gasping breaths are called agonal respirations (also called agonal gasps) and occur when the respiratory centers in the brain continues to send signals to the respiratory muscles. Agonal respirations are not adequate because they are infrequent, gasping respiratory efforts that produce very little, if any, tidal volume. Patients with agonal respirations require artificial ventilation.

A properly placed oropharyngeal airway: A: will not stimulate a conscious patient's gag reflex. B: prevents aspiration if the patient regurgitates. C: keeps the tongue off of the posterior pharynx. D: eliminates the need to perform a head tilt-chin lift.

C: keeps the tongue off of the posterior pharynx. Reason: The oropharyngeal (oral) airway is an artificial adjunct used to keep the tongue away from the posterior pharynx (back of the throat), thus preventing it from blocking the upper airway. It is used in conjunction with, not in lieu of, the head tilt-chin lift or jaw-thrust maneuver to maintain patency of the airway. The oral airway will not prevent aspiration if the patient regurgitates because it does not occlude the esophagus or protect the trachea. The oral airway is contraindicated in conscious patients and in all patients, even those who are unconscious, who have an intact gag reflex. Stimulation of the gag reflex may cause vomiting and aspiration.

The lower airway begins at the: A: cricoid cartilage. B: trachea. C: larynx. D: epiglottis.

C: larynx. Reason: Anatomically, the lower airway begins at the larynx (voice box). The cricoid cartilage is a firm cartilage ring that forms the inferior (lower) part of the larynx. The trachea is connected to the larynx and extends downward to form the left and right mainstem bronchi. The epiglottis is an upper airway structure; it is a leaf-shaped structure above the larynx that prevents food and liquid from entering the trachea during swallowing.

While managing a patient with acute shortness of breath, you attempt to apply a nonrebreathing mask set at 12 L/min. The patient pulls the mask away from his face, stating that it is smothering him. You should: A: inform the patient that refusing oxygen may result in his death. B: increase the oxygen flow and reapply the mask. C: reassure the patient and apply a nasal cannula instead. D: securely tape the oxygen mask to the patient's face.

C: reassure the patient and apply a nasal cannula instead. Reason: Some adults cannot tolerate the oppressive feeling of an oxygen mask over their face; children are typically less tolerant than adults. You should provide reassurance to the patient and apply a nasal cannula at 2 to 6 L/min, which will likely be better tolerated. Do not force an oxygen mask on a patient's face; doing so will only increase his or her anxiety, which will increase his or her body's oxygen consumption and demand.

Tidal volume is defined as the: A: total volume of air that the lungs are capable of holding. B: volume of air moved in and out of the lungs each minute. C: volume of air inhaled or exhaled per breath. D: volume of air that remains in the upper airway.

C: volume of air inhaled or exhaled per breath. Reason: Tidal volume (VT) is the amount of air that is inhaled or exhaled per breath; it is normally 500 mL in a healthy adult male. Tidal volume is assessed by noting the depth of a patient's breathing. Shallow breathing, for example, indicates a reduced tidal volume. The volume of air that remains in the upper respiratory tract (eg, larger bronchi, trachea) is called dead space volume (VD); it is approximately 30% of the adult male's tidal volume and does not participate in pulmonary gas exchange. The volume of air that moves in and out of the lungs each minute, and does participate in pulmonary gas exchange, is called alveolar minute volume (VA). It is calculated by multiplying the tidal volume (minus the dead space volume) and the respiratory rate. Therefore, if an adult male has a tidal volume of 500 mL and a respiratory rate of 18 breaths/min, his alveolar minute volume is 6,300 mL (500 mL [VT] - 150 mL [VD] × 18 [breaths/min] = 6,300 mL [VA]). The maximum volume of air that the lungs are capable of holding is called the total lung capacity (TLC); it is approximately 6 L in the healthy adult male.

A woman presents with acute shortness of breath. Her breathing appears labored and her skin is pale. You should: A:place her supine and assist her ventilations with a bag-mask device. B:ensure that her oxygen saturation does not fall below 85 percent. C:administer high-flow oxygen and assess the quality of her breathing. D:deliver humidified oxygen and administer an inhaled bronchodilator.

C:administer high-flow oxygen and assess the quality of her breathing. Reason: labored does not mean shallow. Let's start with oxygen. Patients with acute respiratory distress and labored breathing need high-flow oxygen. You should then assess the patient for signs of inadequate ventilation and provide ventilatory assistance if needed. Patients with labored breathing will probably not allow you to place them in a supine position as this will make it more difficult for them to breathe. An inhaled bronchodilator is indicated if you hear wheezing when auscultating the patient's lung sounds, which you have not done at this point. You should administer oxygen in a concentration sufficient to maintain an oxygen saturation that is equal to or greater than 94 percent.

Patients with a hypoxic drive: A:are accustomed to low levels of carbon dioxide in the blood. B:may hypoventilate if given low concentrations of oxygen. C:are stimulated to breathe by low oxygen levels in the blood. D:rarely become cyanotic because of high blood oxygen levels.

C:are stimulated to breathe by low oxygen levels in the blood. Reason: Patients with chronic respiratory diseases (eg, emphysema) maintain decreased levels of oxygen and increased levels of carbon dioxide in the blood. The sensors in the brain become accustomed to this. Unlike a healthy person, whose primary respiratory drive is influenced by increasing carbon dioxide levels in the blood, the primary respiratory drive of a patient with a chronic respiratory disease is influenced by low levels of oxygen in the blood (hypoxic drive). Cyanosis is common due to chronic hypoxemia. Some patients with the hypoxic drive may hypoventilate if given high concentrations of supplemental oxygen, although this is highly uncommon. High-flow supplemental oxygen may fool the brain into thinking the body has sufficient oxygen, causing it to send fewer signals to the diaphragm and intercostal muscles.

A 40-year-old man is conscious, but has an increased rate of breathing. You should: A:assist his ventilations with a bag-mask device. B:apply 100% oxygen via nonrebreathing mask. C:assess the regularity and quality of breathing. D:immediately insert a nasopharyngeal airway.

C:assess the regularity and quality of breathing. Reason: You must assess ALL parameters of a patient's breathing—rate, regularity, depth, and quality. If a patient is breathing outside the normal ranges for his or her age, you should assess the depth, quality, and regularity of the respirations in order to determine overall breathing adequacy. On the basis of this assessment, the most appropriate treatment can be provided—oxygen via a nonrebreathing mask or some form of positive-pressure ventilation (ie, bag-mask ventilations). Breathing adequacy is not determined by respiratory rate alone. Conscious patients do not require an artificial airway adjunct (ie, oral or nasal airway).

To ensure you deliver the highest concentration of oxygen with a nonrebreathing mask, you should: A:set the flow rate to at least 10 to 12 L/min. B:cover the flapper valves on the oxygen mask. C:make sure that the reservoir bag is preinflated. D:securely fasten the mask to the patient's face.

C:make sure that the reservoir bag is preinflated. Reason: To ensure delivery of high-flow (greater than 90%) oxygen to your patient with a nonrebreathing mask, you must first set the flowmeter to 15 L/min and then preinflate the reservoir bag. When the patient inhales, pure oxygen is inspired directly from this bag. The valves on the sides of the mask close during inhalation, which prevents outside carbon dioxide from mixing with the oxygen in the reservoir; they open during exhalation, which allows the patient to eliminate carbon dioxide. Following inflation of the reservoir, apply the mask to the patient and ensure that it is secured so as to prevent as much air leakage as possible.

Snoring respirations in an unresponsive patient are usually the result of: A:swelling of the upper airway structures. B:foreign body airway obstruction. C:upper airway obstruction by the tongue. D:collapse of the trachea during breathing.

C:upper airway obstruction by the tongue. Reason: In an unresponsive patient, the muscles of the tongue, which attach to the mandible, relax and fall back over the posterior pharynx. This makes obstruction by the tongue the most common cause of airway obstruction in the unresponsive patient. Foreign body upper airway obstructions and upper airway swelling typically produce stridor, a high-pitched sound heard during inhalation. Collapsing of the trachea during breathing would likely present with marked respiratory distress.

Which of the following patients has signs of inadequate breathing? A: A 30-year-old man with respirations of 12 breaths/min with adequate depth B: A 50-year-old woman with respirations of 12 breaths/min and pink, dry skin C: A 60-year-old man with clear and equal breath sounds bilaterally D: A 41-year-old woman with shallow respirations of 14 breaths/min

D: A 41-year-old woman with shallow respirations of 14 breaths/min Reason: Although the 41-year-old woman has a respiratory rate that falls within the normal range for an adult, the depth of her breathing is shallow (reduced tidal volume). Signs of inadequate breathing in the adult include a slow (less than 12 breaths/min) or fast (greater than 20 breaths/min) respiratory rate, shallow depth (reduced tidal volume), altered level of consciousness, tachycardia, an irregular pattern of inhalation and exhalation, diminished breath sounds during auscultation, and cyanosis. It is important to assess ALL components of a patient's breathing: rate, regularity, depth, and quality. Do not rely solely on one parameter.

Which of the following clinical findings is MOST consistent with a chronic respiratory disease? A: Use of accessory muscles B: Altered mental status C: An irregular pulse D: A barrel-shaped chest

D: A barrel-shaped chest Reason: In certain lung diseases (eg, emphysema, asthma), air is gradually and continuously trapped in the lungs in increasing amounts; this increases the anterior-posterior (front to back) diameter of the chest, causing the chest to assume a barrel shape. A barrel-shaped chest indicates a chronic respiratory disease. Accessory muscle use and an altered mental status in a patient with respiratory distress should be assumed to be acute findings. An irregular pulse could be the result of a primary cardiac problem, or a cardiac problem secondary to chronic hypoxemia in patients with various respiratory diseases.

A 22-year-old man crashed his motorcycle into a tree. He is found approximately 20 feet away from his bike and is responsive to pain only. He is not wearing a helmet. You are unable to effectively open his airway with the jaw-thrust maneuver. What should you do? A: Insert an oral airway and assess his breathing. B: Apply high-flow oxygen and assess his carotid pulse. C: Suction his oropharynx and reattempt the jaw-thrust. D: Carefully tilt his head back and lift up on his chin.

D: Carefully tilt his head back and lift up on his chin. Reason: Regardless of the situation, you MUST be able to establish and maintain a patent airway. Without a patent airway, the patient will die. If you are unable to effectively open a trauma patient's airway with the jaw-thrust maneuver, you should carefully perform the head tilt-chin lift maneuver. You cannot assess, not to mention treat, a patient's airway if it is not open and clear of secretions or foreign bodies.

Which of the following describes the correct technique for inserting a nasopharyngeal airway? A: Apply firm, gentle pressure if you meet resistance during insertion. B: Rotate the device as you insert it into the right nostril. C: Insert the device with the bevel facing the lateral part of the nose. D: Insert the device with the bevel facing the septum.

D: Insert the device with the bevel facing the septum. Reason: Lubricate the nasopharyngeal airway with a water-soluble gel. Insert it into the larger nostril with the curvature following the floor of the nose. If using the right nostril, the bevel should face the septum. If using the left nostril, insert the device with the tip pointing upward, which will allow the bevel to face the septum. Gently advance the airway. If using the left nostril, insert the device until slight resistance is met, and then rotate it 180 degrees into position. This rotation is not required if using the right nostril. Continue until the flange of the device rests against the nostril. If you feel any resistance or obstruction, remove the device and insert it into the other nostril. Forcing the airway into place may cause trauma to the nasal mucosa and unnecessary bleeding, which the patient could potentially aspirate.

Which of the following statements regarding the head tilt-chin lift maneuver is correct? A: It is the technique of choice for patients with potential spinal injury. B: It can only be used in conjunction with an oropharyngeal airway. C: It should be used on all unresponsive patients that you encounter. D: It should be used in conjunction with an appropriate airway adjunct.

D: It should be used in conjunction with an appropriate airway adjunct. Reason: In an unresponsive patient without a suspected spinal injury, the head tilt-chin lift maneuver is the recommended method for opening the airway. To aid in maintaining a patent airway, an appropriate airway adjunct (ie, oral or nasal airway) should be used in conjunction with the head tilt-chin lift maneuver. When inserted properly, the oral or nasal airway will keep the tongue off of the posterior pharynx. You must remember that even once an airway adjunct has been placed, proper positioning of the head must be maintained until the airway is secured more definitively (ie, endotracheal intubation). If you suspect that the unresponsive patient has a spinal injury, the jaw-thrust maneuver should be used; however, if the jaw-thrust maneuver does not adequately open the patient's airway, the head tilt-chin lift maneuver should be used.

Which of the following would MOST likely occur if an adult patient is breathing at a rate of 45 breaths/min with shallow depth? A: The volume of air that reaches the alveoli would increase significantly. B: The lungs would become hyperinflated, potentially causing a pneumothorax. C: Alveolar minute volume would increase due to the rapid respiratory rate. D: Most of his or her inhaled air will not go beyond the anatomic dead space.

D: Most of his or her inhaled air will not go beyond the anatomic dead space. Reason: Alveolar minute volume, the amount of air that reaches the alveoli per minute and participates in pulmonary respiration, is affected by tidal volume, respiratory rate, or both. If the respiratory rate decreases, tidal volume must increase in order to maintain adequate alveolar minute volume. Conversely, if tidal volume decreases, the respiratory rate must increase accordingly. However, if the respiratory rate is extremely fast, especially if the depth of breathing is shallow (reduced tidal volume), most of the inhaled air will only make it to the anatomic dead space (ie, trachea, larger bronchi) before it is promptly exhaled. As a result, alveolar minute volume would decrease, resulting in inadequate pulmonary respiration and hypoxia. For this reason, patients with rapid, shallow breathing often require ventilation assistance. Pulmonary hyperinflation would not be an issue in a patient with exceedingly fast breathing and reduced tidal volume because very little air is actually reaching the lungs.

46. Which of the following is the preferred initial method for providing artificial ventilations to an apneic adult? A: Flow-restricted, oxygen-powered ventilation device B: One-person bag-valve-mask technique with 100% oxygen C: Two-person bag-valve-mask technique with 100% oxygen D: Mouth-to-mask technique with supplemental oxygen

D: Mouth-to-mask technique with supplemental oxygen Reason: The preferred initial method for providing artificial ventilations is the mouth-to-mask technique with one-way valve and supplemental oxygen attached. Evidence has show that rescuers who ventilate patients infrequently have difficulty maintaining an adequate seal with a bag-mask device. Because both of the rescuer's hands are freed up when using a pocket face mask, it is easier to maintain an adequate seal, thus providing more effective ventilations. Of course, if two rescuers are available to manage the airway, the two-person bag-mask device technique should be used. The flow-restricted, oxygen-powered ventilation device, also referred to as the manually-triggered ventilator or demand valve, requires an oxygen source to function and would thus not be practical as an initial device for providing artificial ventilations.

Which of the following ventilation techniques will enable you to provide the greatest tidal volume AND allow you to effectively assess lung compliance? A: Flow-restricted, oxygen-powered ventilation B: One-rescuer bag-mask ventilation C: One-rescuer demand valve ventilation D: One-rescuer mouth-to-mask ventilation

D: One-rescuer mouth-to-mask ventilation Reason: Because the EMT uses both of his or her hands to obtain a mask seal, the one-rescuer mouth-to-mask ventilation technique will provide the greatest tidal volume compared to the other methods listed. Furthermore, lung compliance, the ability of the lungs to expand when ventilated, can be effectively assessed because air is directly blown into the patient's lungs from the EMT's mouth. The one-rescuer bag-mask ventilation technique may allow the EMT to get a sense of lung compliance; however, because maintaining an adequate mask-to-face seal is often difficult, lesser tidal volume can be given relative to the mouth-to-mask technique. The flow-restricted, oxygen-powered ventilation device (eg, manually triggered ventilator, demand valve) provides excellent tidal volume; however, because it is a mechanical device, it does not allow the EMT to assess lung compliance.

A patient's skin will MOST likely become cyanotic if he or she has: A: a decrease in the amount of carbon dioxide. B: an increase in the amount of arterial oxygen. C: an overall increase in circulating red blood cells. D: a decrease in the amount of arterial oxygen.

D: a decrease in the amount of arterial oxygen. Reason: Cyanosis, a blue or purple tint to the skin, reflects an inadequate amount of oxygen in the arterial blood. More specifically, cyanosis indicates that a significant amount of hemoglobin has separated from the red blood cells (desaturation), which makes the arterial blood less able to carry oxygen. An overall increase in the number of circulating red blood cells (polycythemia), would likely cause a patient's skin to remain pink, not become cyanotic. Patients with cyanosis must be given high-flow oxygen and, if needed, positive-pressure ventilations if they are apneic or breathing inadequately (eg, fast or slow rate, shallow breathing [reduced tidal volume]).

Occasional, irregular breaths that may be observed in a cardiac arrest patient are called: A: ataxic respirations. B: Biot respirations. C: Cheyne-Stokes respirations. D: agonal gasps.

D: agonal gasps. Reason: Occasional, irregular breaths, called agonal gasps, may be observed in some patients shortly after their heart stops beating. They occur when the respiratory center in the brain sends stray signals to the respiratory muscles. Agonal gasps are not adequate because they are infrequent and result in negligible tidal volume. Biot respirations are characterized by an irregular pattern, rate, and depth of breathing with intermittent periods of apnea; they are commonly associated with severe brain trauma. Ataxic respirations are ineffective, irregular breaths that may or may not have an identifiable pattern; they are also commonly associated with severe brain trauma. Cheyne-Stokes respirations are characterized by a crescendo-decrescendo pattern of breathing with a period of apnea between each cycle (fast, slow, apnea). Cheyne-Stokes respirations may occur in healthy people during certain phases of the sleep cycle; however, if they are grossly exaggerated or occur in a patient with a head injury, they are an ominous sign.

During your assessment of an unresponsive adult female, you determine that she is apneic. You should: A: place an oropharyngeal airway. B: begin chest compressions. C: deliver two rescue breaths. D: assess for a carotid pulse.

D: assess for a carotid pulse. Reason: As soon as you determine that an adult patient is apneic or only has agonal gasps, you should assess for a carotid pulse for at least 5 seconds but no more than 10 seconds. If the patient has a pulse, provide rescue breathing at a rate of 10 to 12 breaths/min (one breath every 5 to 6 seconds). If the patient does not have a pulse, perform 30 chest compressions and then open the airway and deliver 2 rescue breaths. When managing a patient who is in cardiac arrest, it is critical to minimize interruptions in chest compressions and to avoid delays in starting chest compressions. After starting CPR, apply the AED as soon as one is available. An airway adjunct should also be inserted as soon as possible.

A 60-year-old woman is experiencing severe respiratory distress. When you ask her a question, she can only say two words at a time. Treatment for her should include: A: insertion of a nasopharyngeal airway. B: applying a nasal cannula set at 2 to 6 L/min. C: applying a nonrebreathing mask set at 15 L/min. D: assisted ventilation with a bag-mask device.

D: assisted ventilation with a bag-mask device. Reason: Because the patient is only able to speak in minimal word sentences (two-word dyspnea) and is experiencing severe respiratory distress, it is unlikely that she is ventilating adequately. Therefore, you should assist her ventilations with a bag-mask device. If her breathing continues as it is, she will become increasingly hypoxic and may lose consciousness. Because this patient is conscious, you must explain to her that every time she takes in a breath, the bag-mask device will be squeezed so that an adequate volume of air can be delivered. Clearly, this can cause the patient great anxiety, so your reassurance during this procedure is important. If the patient will not tolerate your attempts to assist her ventilations, apply a nonrebreathing mask and monitor her closely.

An unresponsive patient's respirations are 26 breaths/min and shallow. The MOST appropriate treatment includes: A: a nonrebreathing mask set at 15 L/min. B: a nasal cannula set at 2 to 6 L/min. C: a simple face mask set at 10 to 12 L/min. D: assisted ventilations with 100% oxygen.

D: assisted ventilations with 100% oxygen. Reason: Shallow respirations (reduced tidal volume) at a rate of 26 breaths/min will not provide adequate minute volume. Therefore, you should assist the patient's ventilations with a bag-mask device and high-flow oxygen. Passive oxygenation devices (eg, nonrebreathing mask, simple face mask, nasal cannula) will be of little benefit to a patient with inadequate breathing. The patient must have adequate tidal volume in order to effectively breath in oxygen from these devices.

Oxygen that is administered through a nasal cannula would be of LEAST benefit to a patient who: A: has COPD and an oxygen saturation of 94%. B: is breathing greater than 12 times per minute. C: is in need of long-term oxygen therapy. D: breathes through his or her mouth.

D: breathes through his or her mouth. Reason: A patient who breathes through the mouth or has a nasal obstruction will get little or no benefit from a nasal cannula. Many patients with COPD (eg, emphysema, chronic bronchitis) require long-term, low-flow oxygen therapy; the nasal cannula is ideal in this situation. Considering their chronic respiratory problem, an oxygen saturation of 94% in a COPD patient is good; in fact, many COPD patients maintain an oxygen saturation lower than 94%, even with supplemental oxygen. A nasal cannula is appropriate to use in patients breathing greater than 12 times per minute, provided they have adequate tidal volume and are not significantly hypoxemic. Regardless of the oxygen delivery device used, you should maintain a patient's oxygen saturation at greater than 94%.

The respiratory system functions by: A: ensuring that adequate oxygen is delivered to the body's tissues. B: removing carbon dioxide from the cells and returning it to the lungs. C: sending messages to the diaphragm that cause it to contract. D: bringing oxygen into the lungs and eliminating carbon dioxide.

D: bringing oxygen into the lungs and eliminating carbon dioxide. Reason: The function of the respiratory system is quite simplistic: it brings oxygen into the lungs and eliminates carbon dioxide. The circulatory system works in conjunction with the respiratory system by ensuring that oxygen is delivered to the body's tissues via the bloodstream and that carbon dioxide is removed from the body's cells and returned to the lungs via the bloodstream. The pons and medulla (respiratory centers in the brainstem) regulate breathing by sending messages to the diaphragm and intercostal muscles (the muscles in between the ribs), causing them to contract; this is a function of the nervous system.

After an adult cardiac arrest patient has been intubated by a paramedic, you are providing ventilations as your partner performs chest compressions. When ventilating the patient, you should: A: deliver 2 breaths during a brief pause in chest compressions. B: deliver each breath over 2 seconds at a rate of 12 to 15 breaths/min. C: hyperventilate the patient to maximize carbon dioxide elimination. D: deliver each breath over 1 second at a rate of 8 to 10 breaths/min.

D: deliver each breath over 1 second at a rate of 8 to 10 breaths/min. Reason: When ventilating an adult cardiac arrest patient with an advanced airway in place (ie, ET tube, multilumen airway, supraglottic airway), you should deliver each breath over a period of 1 second—just enough to produce visible chest rise—at a rate of 8 to 10 breaths/min (one breath every 6 to 8 seconds). Do not attempt to synchronize ventilations with chest compressions once the airway has been secured with an advanced device. Hyperventilation should be avoided as it may result in increased intrathoracic pressure, decreased blood return to the heart, and as a result, less effective chest compressions.

A nonrebreathing mask is MOST appropriate to use on patients who: A: are semiconscious and breathing shallowly. B: are breathing less than 12 times per minute. C: are cyanotic and have a low oxygen saturation. D: have an adequate rate and depth of breathing.

D: have an adequate rate and depth of breathing. Reason: With the oxygen flow rate set at 15 L/min, the nonrebreathing mask can deliver an oxygen concentration of 90% or greater. Unlike the bag-mask or pocket mask devices, which deliver oxygen via positive pressure, the nonrebreathing mask delivers oxygen passively; therefore, the patient must have an adequate rate and depth (tidal volume) of breathing in order to open the one-way valve in the nonrebreathing mask and inhale oxygen from the reservoir bag. Shallow (reduced tidal volume) breathing, bradypnea (slow breathing), cyanosis, a low oxygen saturation, and a decreased level of consciousness are signs of inadequate breathing, and should be treated with some form of positive-pressure ventilation assistance.

An unresponsive apneic patient's chest fails to rise after two ventilation attempts. You should: A: reposition the head and reattempt to ventilate. B: attempt to ventilate again using more volume. C: suction the airway and reattempt ventilations. D: immediately proceed to chest compressions.

D: immediately proceed to chest compressions. Reason:If your initial attempt to ventilate an apneic patient is unsuccessful (that is, you meet resistance or the chest fails to visibly rise), reposition the patient's head and reattempt to ventilate. If the second ventilation is unsuccessful, you should proceed under the assumption that the patient has a severe (complete) airway obstruction. Perform 30 chest compressions, open the airway, and visualize the mouth (remove an object only if you can see it). If you are able to remove the foreign object, attempt to ventilate. If you are not, continue chest compressions. Continue this sequence until the obstruction is relieved or an advanced life support (ALS) ambulance arrives. If ALS response will be delayed, transport, continuing your attempts to relieve the obstruction en route, and coordinate a rendezvous with the ALS unit.

While providing initial ventilations to an apneic adult with a bag-mask device, you note minimal rise of the chest despite an adequate mask-to-face seal. You should: A: attach an oxygen reservoir to the bag-mask device. B: suction the airway for up to 15 seconds. C: switch to a smaller mask for the bag-mask device. D: increase the volume of your ventilations.

D: increase the volume of your ventilations. Reason: You must deliver adequate tidal volume to the patient to cause sufficient chest rise. If initial ventilations cause minimal rise of the patient's chest despite an adequate mask-to-face seal, you should increase the volume of ventilations by squeezing the bag harder until the chest rises adequately. Squeeze the bag with just enough force to cause adequate chest rise. Do not routinely suction the patient's airway unless there are secretions in the mouth, as evidenced by a gurgling sound during ventilations. Switching to a smaller mask would likely be ineffective as air would probably leak from around the mask. Attach the oxygen reservoir to the bag-mask device as soon as possible; although this does not influence the volume of air delivered to the patient, it does allow you to deliver a higher concentration of oxygen.

A patient with a mild foreign body airway obstruction: A: presents with a weak cough. B: has a low oxygen saturation. C: has progressive difficulty breathing. D: is typically not cyanotic.

D: is typically not cyanotic. Reason: Patients with a mild (partial) airway obstruction are able to move adequate amounts of air, but will have varying degrees of respiratory distress. The patient can cough forcefully, although you may hear wheezing in between coughs. Because the patient is able to move air effectively, the level of oxygen in his or her blood remains adequate; therefore, cyanosis is typically absent. By contrast, the patient with a severe (complete) airway obstruction cannot move air effectively and cannot speak. If a cough is present, it is weak and ineffective. As the level of oxygen in the blood falls, cyanosis develops, oxygen saturation falls, and the patient's level of consciousness decreases. A foreign body airway obstruction, mild or severe, is an acute event that presents with an acute onset of difficulty breathing. Progressive (gradually worsening) difficulty breathing is more consistent with diseases such as congestive heart failure and pneumonia.

A 60-year-old female is found unresponsive. She is cyanotic, is making a snoring sound while she breathes, and has a slow respiratory rate. You should: A: insert an airway adjunct. B: ventilate her with a bag-mask device. C: suction her airway for 15 seconds. D: manually open her airway.

D: manually open her airway. (Open her airway, assess her breathing, then worry about an adjunct---Open, assess, insert/treat) Reason: Before you can assess and manage a patient's breathing, you must ensure that his or her airway is open first; this patient's airway is not open! Snoring respirations indicate partial blockage of the airway by the tongue. Manually open her airway, using the head tilt-chin lift or jaw-thrust maneuver, and ensure that her airway is clear of secretions. If needed, suction her oropharynx for up to 15 seconds. After manually opening her airway and removing any secretions with suction, insert an airway adjunct (eg, oral or nasal airway) to assist in maintaining airway patency. Slow respirations and cyanosis in an unresponsive patient are obvious signs of inadequate breathing; assist the patient's ventilations with a bag-mask device and high-flow supplemental oxygen.

Ventilation is defined as the: A: exchange of oxygen and carbon dioxide at the cell level. B: elimination of carbon dioxide from the body. C: volume of air inhaled into the lungs in a single breath. D: movement of air into and out of the lungs.

D: movement of air into and out of the lungs. Reason: Ventilation is defined as the movement of air into and out of the lungs. During negative-pressure ventilation (normal breathing), the diaphragm and intercostal muscles contract, which increases the vertical and horizontal dimensions of the chest cavity. As a result, a vacuum is created in the chest and air is drawn into the lungs. Positive-pressure ventilation is the act of forcing air into the lungs (ie, bag-mask ventilation). The volume of air inhaled or exhaled in a single breath is called tidal volume. The exchange of gases between the body and its environment is called respiration; therefore, the exchange of oxygen and carbon dioxide at the cell level is called cellular (internal) respiration. During pulmonary (external) respiration, oxygen and carbon dioxide are exchanged in the lungs; oxygenated blood returns to the left side of the heart and carbon dioxide is eliminated from the body during exhalation.

During your initial attempt to ventilate an unresponsive apneic patient, you meet resistance and do not see the patient's chest rise. You should: A: assume that a foreign body is blocking the airway. B: begin CPR, starting with chest compressions. C: suction the airway for no longer than 15 seconds. D: reposition the head and reattempt to ventilate.

D: reposition the head and reattempt to ventilate. Reason: If your initial attempt to ventilate a patient is met with resistance and/or does not make the chest visibly rise, you should reposition the patient's head and reattempt to ventilate. In many cases, this simple action will open the airway and enable you to ventilate the patient. However, If both of your breaths are met with resistance and/or do not make the chest visibly rise, you should assume that a foreign body is obstructing the airway and begin chest compressions. The airway should be suctioned if secretions are present in the mouth; if oral secretions are not present, do not suction.

If the level of CO2 in the arterial blood increases: A: the respiratory rate slows significantly. B: the respiratory rate and depth decrease. C: a reduction in tidal volume will occur. D: the respiratory rate and depth increase.

D: the respiratory rate and depth increase. Reason: Special receptors, called chemoreceptors, sense the levels of oxygen and carbon dioxide in the arterial blood. The central chemoreceptors are located in the brain; the peripheral chemoreceptors are located in the aorta and carotid arteries. The level of carbon dioxide in the arterial blood stimulates the healthy patient to breathe (primary respiratory drive). If the carbon dioxide level rises above normal, the chemoreceptors send messages to respiratory centers in the brain, resulting in an increase in respiratory rate and depth (tidal volume). Conversely, if the level of carbon dioxide is too low, respiratory rate and depth decrease accordingly.

Which of the following is the MOST correct technique for ventilating an apneic adult who has a pulse? A:Deliver each breath over 1 second at a rate of 8 to 10 breaths/min. B:Ventilate at a rate of 15 breaths/min and look for visible chest rise. C:Hyperventilate at a rate between 20 and 24 breaths/min. D:Deliver each breath over 1 second at a rate of 10 to 12 breaths/min.

D:Deliver each breath over 1 second at a rate of 10 to 12 breaths/min. Reason: When ventilating an apneic adult who has a pulse, deliver each breath over a period of 1 second, at a rate of 10 to 12 breaths/min (one breath every 5 to 6 seconds), while observing for visible chest rise. A ventilation rate of 8 to 10 breaths/min (one breath every 6 to 8 seconds) is appropriate for infants (except newborns), children, and adult patients in cardiac arrest after an advanced airway device (eg, ET tube, multilumen airway, supraglottic airway) has been inserted. Do NOT hyperventilate the patient; doing so may impede blood return to the heart, thus reducing cardiac output, secondary to hyperinflation of the lungs. Hyperventilation also increases the incidence of gastric distention, regurgitation, and aspiration.

Which of the following occurs during positive-pressure ventilation? A:The esophagus remains closed B:Oxygen is pulled into the lungs C:Blood is drawn back to the heart D:Intrathoracic pressure increases

D:Intrathoracic pressure increases Reason: Negative-pressure ventilation, the act of normal breathing, occurs when the diaphragm and intercostal muscles contract. The actions of these muscles create a vacuum (negative pressure), which pulls oxygen-rich air into the lungs. Because of the negative pressure created in the chest, blood is naturally drawn back to the heart. The esophagus remains closed during normal breathing. In contrast, positive-pressure ventilation involves the forcing of air into the lungs, such as what is provided during rescue breathing. Positive-pressure ventilation causes an increase in intrathoracic pressure, which can impair blood flow back to the heart and cause a decrease in cardiac output. During positive-pressure ventilation, the esophagus is forced open and air enters the stomach (gastric distention); this could result in vomiting and aspiration.

Which of the following statements regarding artificial ventilation of an apneic patient who has dentures is correct? A:The EMT should not attempt to remove a patient's dentures because this may cause an airway obstruction. B:Because of the risk of airway obstruction, the EMT should routinely remove a patient's dentures. C:If a patient's dentures are loose, the EMT should use the jaw-thrust maneuver to keep the airway open. D:Tight-fitting dentures should be left in place because they facilitate the delivery of adequate tidal volume.

D:Tight-fitting dentures should be left in place because they facilitate the delivery of adequate tidal volume. Reason: Providing artificial ventilation with a bag-mask or pocket face mask device is usually much easier when dentures can be left in place. Leaving the dentures in place provides "structure" to the face and will assist you in maintaining a good mask-to-face seal, thus facilitating the delivery of adequate tidal volume. However, loose dentures make it much more difficult to perform artificial ventilation by any method and can easily obstruct the airway. Therefore, dentures and dental appliances that do not stay firmly in place should be removed. When ventilating a patient who has dentures or a dental appliance, periodically reassess his or her airway to ensure they remain firmly in place.

The MOST effective way to determine if you are providing adequate volume during artificial ventilation is: A:assessing the pulse for an improving heart rate. B:checking the skin for improvement of cyanosis. C:checking the pupils for increased reactivity. D:assessing the chest for adequate rise.

D:assessing the chest for adequate rise. Reason:The goal of providing artificial ventilation is to provide adequate tidal volume to the patient so that enough oxygen is delivered to the lungs, and ultimately, the cells of the body. The most effective way to determine if adequate tidal volume is being delivered is to watch for the chest to rise during each ventilation. Other signs of adequate artificial ventilation include improvement in skin color, the return of the heart rate to a normal range, and ensuring that you are ventilating the patient at the appropriate rate. If the adult is apneic but has a pulse, provide 10 to 12 breaths/min. If the adult is apneic and pulseless, provide 8 to 10 breaths/min after an advanced airway device (ie, ET tube, multilumen airway, supraglottic airway) has been inserted.

When suctioning copious secretions from a semiconscious adult's airway, you should: A:apply suction as you carefully insert the catheter into the mouth. B:suction for up to 20 seconds while withdrawing the catheter. C:use a flexible catheter because it will remove the secretions faster. D:avoid touching the back of the airway with the suction catheter.

D:avoid touching the back of the airway with the suction catheter.Reason: When suctioning a patient's airway, especially if he or she is semiconscious, you should avoid touching the back of the airway with the suction catheter. Inserting the catheter too far may stimulate the gag reflex, cause vomiting, and increase the risk of aspiration. Rigid (tonsil-tip) catheters are best for removing large amounts of fluid from the airway. Flexible (whistle-tip) catheters are used in situations in which rigid catheters cannot be used, such as with a patient who has a stoma, patients whose teeth are clenched, or if suctioning the nose is necessary. Apply suction while you are withdrawing the catheter. In the adult, suction for no longer than 15 seconds (10 seconds in children, 5 seconds in infants); suction not only removes secretions from the airway, it also removes oxygen.

If an adult patient presents with a respiratory rate of 26 breaths/min, your initial action should be to: A:begin assisting his ventilations with a bag-mask device. B:apply oxygen via a nonrebreathing mask and take his vital signs. C:apply the pulse oximeter and assess his oxygen saturation. D:evaluate his mental status and the depth of his respirations.

D:evaluate his mental status and the depth of his respirations. Reason: must assess mental status to determine o2 or bvm The normal respiratory rate for an adult at rest is 12 to 20 breaths/min. If a patient presents with a respiratory rate outside of the normal range, you should immediately assess him or her for other signs of inadequate breathing, such as a decreased level of consciousness, shallow breathing (reduced tidal volume), brief inhalations followed by prolonged exhalations, and cyanosis. If the patient is conscious, alert, and has adequate tidal volume (eg, his or her chest rises adequately with each breath), supplemental oxygen via nonrebreathing mask or nasal cannula would be appropriate, depending on his or her chief complaint and oxygen saturation. However, if the patient's mental status is decreased and his or her tidal volume is reduced (eg, shallow breathing), some form of positive-pressure ventilation should be initiated (eg, bag-mask or pocket face mask ventilations). It is important to note that breathing adequacy is not determined solely by the patient's respiratory rate; you must assess all aspects of breathing (rate, regularity, depth) as well as the patient's mental status. A patient can be breathing at a "normal" rate; however, if his or her tidal volume is reduced, minute volume will decrease and some form of positive-pressure ventilation may be required.

While ventilating an apneic patient with a bag-mask device, you note minimal rise of the chest each time you squeeze the bag. You should: A:suction the patient's mouth for 15 seconds and reattempt ventilations. B:squeeze the bag harder to ensure delivery of adequate tidal volume. C:ensure that the reservoir is properly attached to the bag-mask device. D:evaluate the mask-to-face seal and the position of the patient's head.

D:evaluate the mask-to-face seal and the position of the patient's head. Reason: If the patient's chest rises minimally or not at all when you are ventilating him or her with the bag-mask device, you should first reevaluate the mask-to-face seal and make sure that the patient's head is properly positioned. The most common complication associated with bag-mask ventilation is difficulty in maintaining an adequate mask-to-face seal. If repositioning the head does not correct the problem, you should ensure that you are squeezing the bag hard enough to deliver adequate tidal volume. Caution must be used, however, when ventilating a patient; breaths that are delivered too forcefully or too fast (hyperventilation) may cause an increase in intrathoracic pressure, thus impeding blood return to the heart and decreasing cardiac output. Forceful ventilations may also cause significant gastric distention. Therefore, you should deliver each breath over a period of one second—just enough to produce visible chest rise. The patient's mouth should be suctioned only if it contains blood or other secretions.

A 56-year-old man has labored, shallow breathing at a rate of 28 breaths/min. He is responsive to pain only. You should: A:place him on his side and administer oxygen via nonrebreathing mask. B:suction his mouth for 15 seconds and insert an oropharyngeal airway. C:ventilate him with a bag-mask device at a rate of 30 breaths/min. D:insert a nasopharyngeal airway and begin assisting his ventilations.

D:insert a nasopharyngeal airway and begin assisting his ventilations. Reason: This patient in this scenario is not breathing adequately. He is responsive to pain only, and his respirations are rapid, labored, and shallow. You should insert a nasopharyngeal airway, which is usually well-tolerated in patients who are semiconscious and have a gag reflex, and assist his ventilations with a bag-mask device. When assisting a patient's breathing, you should squeeze the bag-mask device to ensure that he or she receives 10 to 12 adequate breaths per minute. Do not hyperventilate the patient as this increases the risks of vomiting and aspiration. Hyperventilation also increases intrathoracic pressure, which may impair venous return to the heart (preload) and cause a decrease in cardiac output. Oxygen via nonrebreathing mask is appropriate for patients who are breathing adequately, but are suspected of being hypoxic. The recovery position (patient is placed on his or her side) is appropriate for unresponsive, uninjured patients with adequate breathing.

When attaching an oxygen regulator to a D cylinder and preparing it for use, you should recall that: A:the cylinder must remain in a standing position at all times or it will not deliver any oxygen. B:the cylinder should be taken out of service and refilled when it contains less than 750 psi. C:a pressure-compensated flowmeter should be used when lying the oxygen cylinder down. D:oxygen supports combustion and should not be used where sparks are easily generated.

D:oxygen supports combustion and should not be used where sparks are easily generated. Reason: Oxygen does not burn or explode; however, it does support combustion. A small spark, even a lit cigarette, can become a flame in an oxygen-rich atmosphere. Therefore, you must ensure that the environment in which you will use oxygen is adequately ventilated, especially in industrial settings where hazardous materials may be present and where sparks are easily generated. Never leave an oxygen cylinder standing unattended; the cylinder can be knocked over, injuring the patient or damaging the equipment. The D cylinder (small cylinder carried to the patient) should be taken out of service and refilled when the pressure inside it falls below 500 psi. The pressure-compensated flowmeter, which contains a ball and float that rises or falls according to the gas flow, can only be used when an oxygen cylinder is upright, which is why it is used with on-board oxygen (M cylinder). The Bourdon-gauge flowmeter does not require the oxygen cylinder to be upright, which is why it is used with D cylinders.

Medications such as albuterol (Ventolin) relieve respiratory distress by: A:dilating the large mainstem bronchi of the airway. B:contracting the smaller airways in the lungs. C:constricting the bronchioles in the lungs. D:relaxing the smooth muscle of the bronchioles.

D:relaxing the smooth muscle of the bronchioles. Reason: Medications such as albuterol (Ventolin) and metaproterenol (Alupent) are in a class of drugs called bronchodilators. They relax the smooth muscle found within the bronchioles in the lungs, which causes them to dilate. This effect opens the air passages and improves the patient's ability to breathe.

A reduction in tidal volume would MOST likely result from: A:increased minute volume. B:flaring of the nostrils. C:accessory muscle use. D:unequal chest expansion.

D:unequal chest expansion. Reason: Unequal (asymmetrical) or minimal expansion of the chest results in a decrease in the amount of air inhaled per breath (tidal volume). Accessory muscle use and nasal flaring are signs of increased work of breathing, which represents an attempt to maintain adequate tidal volume (and therefore, minute volume). An increase in tidal volume, respiratory rate, or both, would result in an increase in minute volume. It should be noted, however, that a markedly fast respiratory rate would cause a natural decrease in tidal volume. For example, a patient breathing at a rate of 40 breaths/min would likely only inhale air into the anatomic dead space before promptly exhaling it.


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